EP3003633A1

EP3003633A1 - Apparatus and method for determining the focus position of a high-energy beam

Info

Publication number: EP3003633A1
Application number: EP13765685.6A
Authority: EP
Inventors: Boris Regaard
Original assignee: Trumpf Werkzeugmaschinen SE and Co KG
Current assignee: Trumpf Werkzeugmaschinen SE and Co KG
Priority date: 2013-05-29
Filing date: 2013-09-13
Publication date: 2016-04-13
Anticipated expiration: 2033-09-13
Also published as: JP2016524539A; CN105246636B; JP6284629B2; DE102013210078B4; PL3003633T3; CN105246636A; EP3003633B1; DE102013210078A1; WO2014191061A1; US20160114434A1; US10399185B2

Abstract

The invention relates to an apparatus (1), more particularly a laser processing head, for determining a focus position (F, F', F'') of a high-energy beam (2), more particularly of a laser beam, in the beam direction (13) of the high-energy beam (2) relative to a workpiece (3) and/or relative to a reference contour (5b) of the apparatus (1), comprising: a focusing element (4) for focusing the high-energy beam (2) onto the workpiece (3), an image capture device (9) for capturing a region to be monitored on the surface (3a) of the workpiece (3) and/or the reference contour (5b) by means of an observation beam path (7) running through the focusing element (4), wherein the image capture device (9) is designed for forming at least one observation beam (7a) which is assigned an observation direction (R1) running non-coaxially with respect to the high-energy beam (2), and comprises an imaging optical unit (14) for generating at least one image of the region to be monitored and/or the reference contour (5b) from the at least one observation direction (R1), and an evaluation device (19) for determining the focus position (F, F', F'') in the beam direction (13) of the high-energy beam (2) by evaluating the at least one recorded image. The invention also relates to a method for determining a focus position (F, F', F'') of a high-energy beam (2) in the beam direction (13) of the high-energy beam (2).

Description

Apparatus and method for determining the focus position of a

High energy beam

The present invention relates to a device for determining a

Focusing position of a high energy beam, in particular a laser beam, in

Beam direction of the high energy beam relative to a workpiece and / or relative to a reference contour of the device. The invention also relates to a method for determining a focus position of a high-energy beam, in particular a laser beam, in the beam direction of the high-energy beam relative to a workpiece and / or relative to a reference contour of a device having a focusing element for focusing the high-energy beam onto the workpiece. The device may, for example, be a machining head, in particular a laser machining head. For workpiece machining, the focus position or the position of the focal plane of a high-energy beam used for workpiece machining is an important parameter. The position of the focal plane or the position of the focus position in

The propagation direction of the high-energy beam is dependent on the divergence or convergence of the high-energy beam in front of the focusing element and on the focal length of the focusing element for the high-energy radiation used, more precisely for the wavelength range of the high-energy radiation or when using a laser beam for its operating wavelength. The divergence or convergence of the high energy beam is usually well controlled and subject to minor adjustments after a basic adjustment. However, the change in the focal length of the focusing element during the. Is critical for large beam powers and especially for CO2 laser radiation

Workpiece machining. If a lens is used as the focusing element, the radial heating and cooling of the lens form a radial one

Temperature gradient resulting in a change in the refractive index n of the lens which depends on the radial coordinate (i.e., n = n (r)). The

Refractive index change in workpiece processing typically leads to a shortening of the focal length (so-called thermal lens). The actual focal length fFL of the focusing lens is thus, inter alia, a function of the beam power P _L and the beam shape (eg the beam diameter D _R ), the degree of soiling of the focusing lens and the time: f _L = f (Pi_, D _R> t,. , To determine the focus position or the position of the focal plane during workpiece machining, it is therefore generally necessary to take into account the actual focal length of the focusing element.

To determine the focus position of a high energy beam in the beam direction, it is u.a. known to make a measurement of the beam path or the Strahlkaustik means of a suitable measuring device or possibly to detect the radiation power only in the vicinity of the beam waist. Also, it is possible at several

each selected intervals between the focusing element and workpiece each introduce a cut in the workpiece and close based on the width of the cut on the focus position relative to the workpiece. The above However, the possibilities described typically do not allow the focus position to be recorded on-line, ie during workpiece machining.

From WO 2011/009594 A1, a laser processing head for processing a workpiece by means of a laser beam has become known. Of the

Laser processing head has a camera with an imaging optics

Observation of a processing area of the workpiece and a focusing lens for focusing the laser beam on the workpiece surface or on a relative to the workpiece surface defined position. Furthermore, the WO describes

201 1/009594 A1 an evaluation unit, which is formed by means of a

Adjustment path of the imaging optics in the direction of the optical axis, which is required to adjust the camera image again sharply when shifting the focus of the focusing lens, to calculate a correction Verstellweg, which is a focus shift of the focusing optic relative to the workpiece surface or relative to the workpiece surface defined position compensated.

DE 10 2010 017 316 A1 describes a system which has a

Welding device, which is set up, a welding bead on a

Apply workpiece. The system may include a plurality of cameras directed to the weld bead and configured to generate a corresponding number of images. A controller generates based on the images

stereoscopic image of the weld bead and represents on the basis of

Stereoscopic image a parameter of the weld bead application. Instead of multiple cameras, a single camera can be used to capture images from two different perspectives or perspectives, as well as perform a differential analysis of the images

to produce stereoscopic image.

From DE 10 2005 032 946 A1 a device for processing an object by means of laser radiation has become known, which has an observation device for imaging the object and a laser scanning device. The

Observation device can as a stereomicroscope with two

Imaging beam paths and two eyepieces are adapted to stereoscopically observe the object in a preparation mode. Through an optical Coupling device can by the same eyepieces and the course of the

Processing process to be tracked during operation of the laser scanning device.

DE 10 201 1016 519 A1 discloses a method and a device for controlling the machining of a workpiece by means of a high-energy

Processing beam described in which the processing beam passes through a lens that can be moved to move a point of impact of the processing beam on the workpiece perpendicular to its optical axis. In one example, a surveillance camera is for generating an electronic

evaluable image provided, the imaging beam path is focused by the lens on the impact site.

In EP 2 456 592 B1, a laser processing head is described which has a

Focusing optics for focusing a working laser beam on the

Having workpiece surface or on a relative to the workpiece surface defined position and a camera with a previously arranged in the beam path imaging optics for observing a processing region of the workpiece. An evaluation unit is provided, which is designed to use an adjustment path of the imaging optics in the direction of the optical axis, which is necessary to sharply adjust the camera image again during a shift of the focus of the focusing lens, to calculate a correction adjustment path, the one

Focus shift of the focusing optics relative to the workpiece surface or to a position defined relative to the workpiece surface compensated. Object of the invention

The invention has for its object to provide an apparatus and a method which allow a reliable determination of a focus position during the machining of a workpiece with a high energy beam.

Subject of the invention

This object is achieved by a device of the aforementioned type, comprising: a focusing element for focusing the high energy beam on the Workpiece, an image detection device for detecting an area to be monitored on the surface of the workpiece and / or the reference contour by means of a passing through the focusing element

Observation beam path, wherein the image capture device is designed to form at least one observation beam, which is a non-coaxial or not parallel to the beam direction of the high-energy beam extending

Observation is assigned and an imaging optics for generating at least one image of the area to be monitored and / or the

Reference contour from the at least one observation direction comprises, as well as an evaluation device, which is used to determine the focus position of the

High energy beam is formed or programmed by evaluating the at least one recorded image.

The measuring principle proposed for determining the focus position in the beam direction of the high-energy beam is based on the detection of at least one image of the area to be monitored or the reference contour of at least one

Viewing angle or at least one observation direction not coaxial with the high energy beam, i. the part of the observation beam path that the

Has passed focusing element, extends at an angle to the optical axis of the focusing element. On the basis of such an observation beam, with suitable evaluation of the recorded image, changes in the focal length of the focusing element or, if appropriate, the object distance, i. detected the distance between the workpiece and focusing element, determines the focus position in the beam direction of the laser beam and corrected if necessary.

In one embodiment, the evaluation device is designed to determine the focus position in the beam direction of the high-energy beam on the basis of a position of the reference contour in the at least one recorded image. In this case, a relative to the device statically arranged reference contour or

Reference geometry, for example, in a device in the form of a

Laser processing head can be formed by a nozzle inner contour of a laser processing nozzle, used to determine the focus position. The

Reference contour has a constant distance in the beam direction to

Focusing element, such as a focusing lens, on. A change in the Focal length of the focusing element, for example by a thermal load, leads to a lateral displacement of the reference geometry in the recorded image.

Based on the size of the lateral displacement of the position of the reference geometry in the captured image, the focus position can be determined. It can also be concluded from the direction of the lateral displacement on the direction of displacement of the focus position from a desired focus position. For this purpose, for example, the deviation or the lateral offset to a reference position of the reference contour in a non-thermally loaded

Focusing be determined. The reference position at the (known) focal length of the focusing element in the cold state, i. without the application of a high-energy beam, can be determined before the evaluation of the image and stored in a memory device associated with the evaluation device, for example in the form of a reference image or a position, e.g. Centroid, the geometric center or a specific geometric feature, such as a geometry edge deposited.

In a further embodiment, the image capture device is designed to form at least one further observation beam which is assigned to a further observation direction, wherein the imaging optical system generates at least two images of the region to be monitored and / or the

Reference contour is formed from the at least two different observation directions, and wherein the evaluation device for determining the

Focusing position of the high energy beam is formed by comparative evaluation of the recorded images.

The measuring principle proposed in this embodiment for determining the focus position is based on a stereoscopic distance measurement by the

Focusing element through, ie on the recording of two or more images of the area to be monitored on the surface of the workpiece or the reference contour mounted in the device from two or more different observation directions or angles. For this purpose, the imaging optics typically form two or more observation beams, usually off-center (ie, not through the central axis) of the focusing element, and thus at different angles to the workpiece. Beam of the imaging or observation beam path on spaced areas of one or more detector surfaces. As an alternative to the generation of two or more images at spaced-apart regions of the detector surface (s), two or more images can also be detected on the same region of a detector surface in short chronological succession, as described in more detail below. The comparative evaluation of three or more images makes it possible to increase the significance of the comparison and thus the accuracy of the determination of the focus position. For the most precise determination possible of the focus position, it is advantageous if the viewing angles or the observation directions under which the images are taken differ as much as possible from each other. A large difference between the viewing angles can be obtained, in particular, when the two images of the surface region of the workpiece to be monitored pass through two diametrically opposite edge regions of the focusing element. As a focusing element typically serve one or more focusing lenses or a focusing mirror, in particular an off-axis parabolic mirror.

When the workpiece is in the focal plane of the focusing lens, the images of the area of the workpiece to be monitored from the peripheral areas of the focusing lens are identical. The two pictures of the too

but the monitoring area on the surface of the workpiece are laterally displaced relative to each other when the workpiece is outside, i. above or below, the focal plane of the focusing lens is located. On the basis of the size of the lateral displacement between the two images can be concluded that the deviation or the distance of the focus position or the focal plane to the workpiece.

Accordingly, based on the lateral distance between two images of the reference contour formed in the device to the focus position relative to

Device or reference contour or reference geometry are closed. To achieve this, the distance between the two images of the

Reference contour of the (known) focal length of the focusing element in the cold state, ie without the application of a high energy beam assigned become. The change in the distance between the two images resulting from the change in the focal length can be assigned to a corresponding change in the focus position. In this way, a focal length measurement of the focusing element or a determination of the focus position relative to

Device and thus independent of the workpiece possible.

To determine the lateral deviation between the images, a

Local correlation of the two images, for example, performed by a block matching algorithm or by a local frequency analysis and the position of maximum agreement are calculated. In contrast to the measurement of image sharpness described in WO 2011/009594 A1, the

Stereoscopic measurement A determination of the focal length deviation both in magnitude and in direction (i.e., toward or away from the workpiece). As a result, rapid control of the focus position or focus position is possible (see above), without having to rely on iterative tracking. It is understood that in the stereoscopic image also the influence of others in the

Imaging beam path located optical elements on the change of the focal length or the change of the focus position is taken into account. For example, this applies to the thermal lens produced by a protective glass which prevents the termination of the device, e.g. in the form of a machining head, forms towards the workpiece.

In one embodiment, the device has an illumination source for illuminating the surface of the workpiece, in particular in the

monitoring area and / or the reference contour. The illumination source can, for example, generate illumination at wavelengths between 360 nm and 800 nm (VIS) or approximately 800 nm and approximately 1000 nm (NIR). The illumination serves to obtain an image of contours on the surface of the workpiece in the region to be monitored or the reference contour formed on the device. The illumination may be coaxial with the high energy radiation, i. in the form of incident illumination. But it is also possible to use the illumination source to illuminate a defined measurement position within the device on which the reference contour or reference geometry is formed. The

Reference contour can, for example, from a directional illumination source irradiated and captured by the image capture device. Furthermore, a cutting nozzle attached to the cutting head for guiding a process gas can be used as reference contour. In one embodiment, the observation or imaging beam path of the image capture device for detecting the area to be monitored on the surface of the workpiece on an image acquisition area, which of the

Reference contour is limited. In this case, the illumination source

For example, illuminate the workpiece or another surface below the reference contour and the reference contour or the reference geometry forms the

Limitation of the lighting or the limitation of the

Image capture device detected image capture area.

In one embodiment, the evaluation device for determining the

Focus position of the high energy beam relative to the workpiece by comparative evaluation of the images of the (rough) surface of the workpiece in the zu

trained monitoring area. In this case, the fact that the surface of the generally plate-shaped workpiece is not completely smooth is utilized for the comparative evaluation or correlation of the two images

(At least in microscopic orders of magnitude) has a roughness and thus a location-dependent varying surface structure. Based on a lateral distance between the surface structures in the different

Observation directions recorded images, the focus position can be determined.

As a rule, the area of the workpiece to be observed comprises one

Interaction area of high energy beam with the workpiece. As an alternative or in addition to the stereoscopic correlation of the images of the contours of the rough workpiece surface, the process lighting (thermal

Radiation, plasma radiation) are used for the stereoscopic evaluation of the two images. In both cases, a structured illumination can be used to illuminate the workpiece, for example in the form of a

focused illumination beam near the interaction region. In one embodiment, the imaging optics has at least two imaging optical elements associated with a respective observation direction. The imaging optical elements may be, for example

Act lens elements. The lens elements may be arranged at a distance from one another that corresponds approximately to the distance between the two images on the detector surface. Each of the two imaging optical elements generates its own imaging or observation beam for generating the respective associated image on the associated area of the detector surface. The two lens elements are typically eccentric, i. not coaxial to the beam path of the high energy beam or to its extension in the

Observation beam arranged. In this way, two or more beams can be imaged, each passing through an edge region of the focusing lens and thus allow observation under two or more different observation angles or observation directions. For example, spherical or aspherical lenses can be used as imaging optical elements. It is understood that, if appropriate, one of the imaging optical elements can be arranged coaxially with the beam path of the high-energy beam, as will be described in more detail below. In a further development, the imaging optical elements are designed as cylindrical lenses. In addition to first cylindrical lenses, which produce a curvature or an imaging effect along a first axis, the imaging optics usually have at least one second cylindrical lens which has an imaging effect along a second, to the first vertical axis. Due to the crossed cylindrical lenses, the imaging optics can on the one hand be produced inexpensively and, on the other hand, the available imaging cross section can be used well.

In a further development, the imaging optical elements are in one

Lens array or arranged in a grid arrangement. A raster arrangement of lens elements ("lenslet"), for example microlenses, also in the form of two crossed cylindrical lens arrays, can be used to form a

Spatially resolved determination of wavefront aberrations caused by the thermally stressed lens element. By the Determination of the wavefront aberrations may be the beam focusing of the

Processing beam can be optimized by means of the focusing element by a suitable focusing element upstream beam shaping and / or it can be a coaxial observation of the workpiece for process monitoring, if necessary, at a different wavelength by a suitable correction of

Observation beam to be improved. The correction of both the beam shape of the machining beam and the observation of the workpiece can

For example, by a suitable adjustment of aperture diameters, by changing the distance of lenses in the beam path, by deformable mirrors, etc. can be realized. The measuring principle for the determination of

Wavefront aberrations represent a modification of the Shack-Hartmann sensor in which a local wavefront tilt is measured by a shift of focus points generated by the lenses of a two-dimensional lens array in the focal plane of the lens array.

In a further embodiment, the imaging optics has a deflection device with at least two associated with a respective observation direction

Beam deflection on. The deflection can be as geometric

Beam splitters serve. For example, the incident radiation can

different areas of an imaging optical element, such as a lens element, are steered. Two beams deflected by the deflecting device and impinging on diametrically opposite regions of the lens element are focused by the lens element on different spaced-apart regions in its focal plane, at which the images of the region to be monitored or the reference contour are generated.

In a further development, the deflection device has at least one deflection prism. At the deflection prism can several, in particular all

Beam deflecting be formed, which may be formed, for example, as at an angle to the beam axis aligned facets or surface areas of the prism. The deflection prism may in particular have a central region in which this is designed as a plane-parallel plate and on which no deflection is made. The beam deflecting areas or

Strahlumlenkflächen can be arranged around the central area, so that overall results in an approximately concave or convex geometry of the deflection prism. As an alternative to the use of a deflecting prism, the deflecting device can also be designed to be reflective and, for example, have a plurality of deflecting regions in the form of mirror surfaces, which comprise the

To redirect observation radiation in different directions, which are assigned to a respective observation direction.

In a further embodiment, the image capture device for forming the at least two associated with a respective observation direction

Observing beams on a Strahlversatzeinrichtung. The

Strahlversatzeinrichtung can in particular in focused

Illumination beam path of the imaging optics, for example, between two a beam telescope forming optical elements, be arranged. The

For example, beam displacing means may comprise one, two or more blocks of material transparent to the illumination radiation, e.g. of quartz glass, which are formed as plane-parallel blocks or plates to produce a parallel offset of the incident observation radiation. The blocks are typically tilted with respect to each other so as to cause the two or more observation beams to be at different areas of the

Detector surface to create two or more laterally offset images.

The image capture device can have a beam splitter to form the at least two observation beams associated with a respective observation direction. The beam splitter can split the observation radiation into two or more observation beams based on at least one property that changes over the beam cross section. The property may be, for example, the polarization direction, the power or the wavelength of the

Observational radiation acting over the cross section of the

Observation beam varies. For the illustration of the respective

Observational beams on a detector surface may be provided in each case a separate imaging optical element, but it is also possible to make the image of the observation beams by means of a common imaging optics, for example in the form of a common focusing lens. In a further embodiment, the image capture device for forming the at least two associated with a respective observation direction

Observation beams formed at different times. In this embodiment, the two or more images are acquired with a (short) time lag (typically in the range of a few microseconds or milliseconds) dependent on the frame rate of the detector or camera of the image capture device. In this way, the two or more images can be generated at one and the same location of a detector surface, i. a spatial separation of the observation beams on the detector surface is not required in this embodiment. For temporally successive recording of the images of the observation beam path is partially shaded, wherein for the recording of an image typically a different part of the

Observation beam is shadowed. In a further embodiment, the image capture device for forming the at least two associated with a respective observation direction

Observation beams at least one aperture, which is in particular formed to form the two or more observation beams at different times or can be controlled. The aperture can be designed for this purpose, for example, as a displaceable, rotatable or switchable aperture. The diaphragm can be used for partial shading of the observation beam path, wherein temporally successive by a suitable control of the diaphragm

different parts of the observation beam path can be shaded. An aperture through which the observation radiation passes typically produces an observation beam which is one of the observation beams

Is assigned observation direction. The bezel may be in the form of an electronic shutter (e.g., a switchable pixel LCD screen) or an electronic shutter

mechanical shutters (e.g., an aperture plate movable (e.g., rotatable or displaceable) aperture plate) and serve to

To hide or open different areas of the observation beam path temporally successive, to produce temporally successive two or more images from different directions of observation. It goes without saying that for high-resolution observation of the area of the workpiece to be monitored with the goal of process observation, further regions of the aperture of the observation beam path can be opened or closed.

In a further embodiment, the imaging optics for generating at least three images of the area to be monitored and / or the

Reference contour formed from different directions of observation. As was shown above, it is usually sufficient for the determination of the focus position to determine the lateral offset along a direction between two images taken from different observation directions. However, the use of three or more images may possibly increase the significance of the comparison or the accuracy of the determination of the focus position. The generation of at least one further (third, fourth,...) Image can also serve to obtain further information about the focusing element, in particular in order to determine its wavefront aberrations, as was shown above. As a result, the change in the focal length of a high-power laser beamed focusing element or a focusing lens depending on location, i.

depending on the radial position with respect to the optical axis of

Focusing element to be determined. With the aid of more than two imaging optical elements (for example in the form of a lens array) or with the aid of more than two beam deflection regions, three or more images of the workpiece surface and / or the reference contour can be generated and recorded on a detector, e.g. a camera, to be imaged.

In a further embodiment, the device comprises at least one imaging optical element for generating an image of the area to be monitored on the surface of the workpiece from a viewing direction coaxial with the high-energy beam. As has been shown above, the contains to

monitoring area usually an interaction area between the high energy beam and the workpiece. With the help of the imaging optical

Elements can be created the process lighting of the process in the VIS area and / or a thermal image of the area to be monitored in the NIR / IR area to obtain information about the machining process, such as a welding or a cutting process. This as well

Process monitoring can be called monitoring of the machining process in addition to the stereoscopic detection of the monitored area or the reference contour.

The imaging optical element can be a lens element, which typically has a larger diameter than the lens elements associated with the respective observation directions, in order to obtain a higher resolution in the imaging. If necessary, the imaging optical element can also be used for the generation of two or more images which are recorded from different observation directions which do not run coaxially or parallel to the propagation direction of the high-energy beam. This is usually the case when the imaging optics has a deflection prism as described above.

In one embodiment, the evaluation device is for comparative

Evaluation of the image recorded coaxially to the high energy beam and formed at least one non-coaxial with the high-energy beam recorded image. The focus position of the high-energy beam can also be determined in the manner described above using the comparative evaluation of a coaxial and at least one image that is not coaxial with the high-energy beam.

In a further embodiment, the image capture device for receiving the at least one image is formed by a nozzle opening of a laser processing nozzle for the passage of the laser beam onto the workpiece. In this so-called coaxial observation, the images of the monitored

A portion of the workpiece is picked up by the processing nozzle (e.g., laser cutting nozzle) and by the focusing element from one or more cameras. The device in this case is typically a laser processing head.

In a development, the nozzle inner contour of the laser processing nozzle, in particular of a laser cutting nozzle, forms the reference contour or reference geometry, which is used for stereoscopic image evaluation. For example, the lateral distance between two images of the usually circular Nozzle inner contour can be determined to make a rough adjustment of the focus position. In this case, it can be utilized that the comparative evaluation of the images of the inner contour of the nozzle opening can be carried out very quickly, since only the distance between the two typical manner is circular

Limits of the captured by the nozzle opening image of the workpiece must be determined. The determination of a lateral offset between the images of the workpiece surface, in which the contours or

Surface geometry of the workpiece must be evaluated, usually requires more computing time and can be used for a fine adjustment of the focus position.

In one embodiment, the image capture device has at least one detector, in particular a camera, with a detector surface on which the at least one image is generated. For the detection of several images, one and the same detector surface can be used e.g. serve in the form of a CCD chip or a CMOS chip of the camera, the images at different portions of the

Detector surface are generated. Particularly in this case, it is favorable if the imaging optics has a beam telescope in order to adapt the imaging cross section to the available detector surface. It goes without saying that two or more cameras can also be provided in the image capture device in order to acquire one or more images on a respective detector surface. In particular, the determination of the position of the reference contour can also take place with a simpler optical sensor or detector, for example a four-quadrant diode or a line scan camera, instead of a surface camera.

In a further embodiment, the evaluation device is designed to determine a distance between the reference contour and the upper side of the workpiece by comparative evaluation of the recorded images. The distance between the reference contour and the workpiece can be determined by determining the difference between the distance of a surface structure at the top of the workpiece, ie an image position of the workpiece surface, to an (identical) position on the reference contour in the two captured images. In one embodiment, the device additionally comprises a device for changing the focus position of the high energy beam in the beam direction and a control and / or regulating device for controlling and / or regulating the

Focus position of the high energy beam to a target focus position relative to

Workpiece. The device for changing the focus position may, for example, be a so-called adaptive mirror whose

Surface curvature can be selectively influenced to change the focus position in the beam direction of the high energy beam. Based on the determined in the manner described above actual focus position, the device can be controlled such that the focus position is controlled to a desired focus position, which typically remains constant during the machining process and, for example, on the workpiece top or a predetermined distance to Workpiece can be located. That way, the top ones

represented by a thermal load of the focusing element

caused changes in the focal length of the focusing element

be compensated. Is the device for changing the

Focus position, i. the actuator, before the measuring position or before the

Observation beam, there is a control of the focus position to the target focus position. From the determination of the focus position on the workpiece and the focal distance of the reference contour in the machining head (for example laser cutting nozzle), the distance of this reference contour to the workpiece surface can be determined (see above) and, if necessary. be controlled or regulated by means of the control and / or regulating device. In a further embodiment, the device additionally comprises a

Device for changing the focus position of the imaging optics in the beam direction of the high-energy beam, and a control and / or regulating device for

Control and / or regulation of the focus position of the imaging optics to a desired focus position. The device for changing the focus position or the

Control element is typically arranged in the observation beam path in this case, so that there is a control of the focus position of the imaging optics to the target focus position. The desired focus position of the imaging optics is typically located on the surface of the workpiece to be observed. The control or regulation to the desired focus position can according to the above in the In connection with the high-energy beam described procedure can be performed.

The invention also relates to a method of the aforementioned type, which comprises the following steps: detecting an area to be monitored on the surface of the workpiece and / or the reference contour by means of an observation beam path passing through the focusing element, generating at least one image of the area to be monitored and / or the

Reference contour by forming at least one observation beam, which is not associated with an observation direction coaxial with the high energy beam, and determining the focus position in the beam direction of the high energy beam by evaluating the at least one recorded image.

In one variant, the focus position in the beam direction of the high energy beam is determined based on a position of the reference contour in the at least one recorded image. As was shown above, the focus position in this case can be determined based on a lateral displacement of the reference contour within the recorded image, for example by comparison with a reference position.

In another variant, at least one more of another

Observation direction associated observation beam formed to generate at least two images of the area to be monitored and / or the reference contour from at least two different observation directions, wherein the focus position of the high energy beam is determined by comparative evaluation of the recorded images. As has been shown above, in the comparative evaluation, a lateral offset between the two

recorded images or to be recognized on these structures, which is a measure of the position of the focus position relative to the reference contour or relative to the workpiece.

The invention also relates to a computer program product comprising code means adapted to perform all the steps of the method described above when the computer program is on a data processing system expires. The data processing system can be, for example, a control and regulating device and / or an evaluation device which is accommodated in a device as described above, but also an external device which is typically part of a processing machine.

Further advantages of the invention will become apparent from the description and the drawings. Likewise, the features mentioned above and the features listed further can be used individually or in combination in any combination. The embodiments shown and described are not to be understood as exhaustive enumeration, but rather have exemplary character for the description of the invention.

FIG. 1a shows a schematic representation of an embodiment of a

Device for determining a focus position of a laser beam on the basis of two images taken through a focusing element, FIG. 1 b shows a plan view of an imaging optical system of the device of FIG. 1 a,

2a-c representations of two images taken from different observation directions of a region of a workpiece to be monitored at different focal positions of the laser beam, a representation of an incident on a focusing lens of the device radial beam profile and a resulting radial refractive index distribution of the focusing lens, Fig. 4a-c Representations of an imaging optics for the device of Fig. 1a, b with a plurality of cylindrical lenses,

5a-c representations of an imaging optics for the device of Fig. 1a, b with a cylindrical lens array, 1a, b with an approximately convexly curved deflection prism, Fig. 7a, b representations of an imaging optics for the device of Fig. 1a, b with an approximately concave curved deflection prism, Fig. 6a, b shows illustrations of an imaging optics for the device of FIG.

8a is a representation of an imaging optics for the device of Fig. 1 a, b with a deflection device with two mirror surfaces,

Fig. 8b is an illustration of an imaging optics for the apparatus of Fig. 1 a, b with a Strahlversatzeinrichtung, and

9 a, b representations of an imaging optical system for the device of FIGS. 1 a, b with a rotatable diaphragm in a side view and in a plan view,

10 is a schematic representation of an embodiment of a

Apparatus for determining a focus position of a laser beam on the basis of an image taken through a focusing element, and

Fig. 1 1 a, b representations of two from the same direction of observation

taken pictures of a reference contour at different focus positions of the laser beam.

In the following description of the drawings are for the same or

functionally identical components identical reference numerals used.

1a shows an example of a construction of a device 1 for focusing a laser beam 2 on a workpiece 3, which is designed in the form of a laser processing head, which is part of a laser processing machine, not shown. The laser beam 2 is generated in the example shown by a C0 ₂ laser.

Alternatively, the laser beam 2 can be generated for example by a solid-state laser. The laser beam 2 is to carry out a workpiece machining the workpiece 3, for example in the form of a laser welding or

Laser cutting process, by means of a focusing element in the form of a

Focusing lens 4 focused on the workpiece 3. The focusing lens 4 in the example shown is a lens made of zinc selenide, which focuses the laser beam 2 on the workpiece 3 through a laser processing nozzle 5, more precisely through its nozzle opening 5a, specifically in the example shown

Focusing position F at the top 3a of the workpiece 3. In the case of a laser beam 2 from a solid-state laser, a focusing lens, for example. From quartz glass can be used.

In Fig. 1 a also visible is a partially transparent trained deflecting mirror 6, which transmits the incident laser beam 2 (with a wavelength of about 10 pm) and for process monitoring relevant observation radiation (for example in the visible wavelength range) to another

partially reflecting deflecting mirror 8 reflected. In the case of a laser beam 2 from a solid-state laser, the deflecting mirror is typically designed to be partially transmissive for a wavelength of approximately 1 μm. The further partially transparent deflection mirror 8 reflects the observation radiation to an image detection device 9. An illumination source 10 serves for the coaxial illumination of the workpiece 3 with illumination radiation 11. The illumination radiation 11 is transmitted by the further partially transmissive deflection mirror 8 and directed through the nozzle opening 5a of the laser processing nozzle 5 onto the workpiece 3. As an alternative to the partially transparent deflecting mirrors 6, 8 and Scraperspiegel or

Hole mirror, which reflect incident radiation only from an edge region, are used to supply the observation radiation 7 of the image capture device 9 and to supply the illumination radiation 1 1 to the workpiece 3. Also, two laterally introduced into the beam path of the laser beam 2 mirror can be used to enable the observation. Diode lasers or LEDs can be provided as the illumination source 10, which can be arranged coaxially as shown in FIG. 1 a, but can also be arranged off-axis to the laser beam axis 13. The illumination source 10 may, for example, also be arranged outside (in particular next to) the device 1 and directed towards the workpiece 3; Alternatively, the illumination source 10 within the device 1 be arranged, but not coaxially aligned with the laser beam 2 on the workpiece 3. Optionally, the device 1 without a

Illumination source 10 are operated. Part of the image capture device 9 is a geometrically arranged in the observation beam path 7 behind the further partially transparent deflection mirror 8

high-resolution camera 12. Camera 12 may be a

Act high-speed camera, which is coaxial with the laser beam axis 13 and the extension of the laser beam axis 13 and thus arranged direction independent. In the illustrated example, the image is captured by the camera 12 in the incident light process in the VIS wavelength range, but it is also possible that the camera 12 takes pictures in the NIR / IR wavelength range to the

Process lights or a thermal image of the machining process

take. It is also possible to take pictures in the UV range in order to record incident light illumination or process (plasma) radiation. In the example shown in FIG. 1 a, a filter can be arranged in front of the camera 12 if further radiation or wavelength components are to be excluded from the detection with the camera 12. The filter may e.g. be designed as a narrowband bandpass filter.

In order to generate images B1, B2 of a region 15 to be monitored on the surface 3a of the workpiece 3 on a detector surface 12a of the camera 12 shown in FIGS. 2a-c, the image capture device 9 has imaging optics 14 which, in the example shown, two in the beam path of FIG Observation beam 7 has arranged lens elements 16a, 16b. The lens elements 16a, 16b are arranged in a common plane and each form only a partial beam or a partial beam of the observation beam path 7, each one

Observation beam 7a, 7b form, on different areas of the detector surface 12a of the camera 12, so that there are two spaced-apart images B1, B2 are generated, as shown in Fig. 2a-c. As can be seen in FIGS. 2 a - c, the region or the image B 1, B 2 of the workpiece 3 respectively imaged by the lens elements 16 a, 16 b is of a circular inner contour 5 b

Laser processing nozzle 5 limited. To the image cross section to the size of Adjusting detector surface 12a, the imaging optics 14 on a beam telescope with two other lenses 17a, 17b.

The respective part (observation beam 7a, 7b) of the observation beam path 7 imaged by the two lenses 16a, 16b on the detector surface 12a originates from two edge regions of the focusing lens 4 which are diametrically opposite one another in the X direction of an XYZ coordinate system and thus form the one to be monitored Area 15 of the workpiece 3 and the inner contour 5b of

Laser processing nozzle 5 from different observation directions R1, R2 or from different observation angles relative to the laser beam axis 13 from. The two lenses 16a, 16b thus allow a stereoscopic observation of the area 15 to be monitored or the inner contour 5b of the

Laser processing nozzle 5. In Fig. 1 a, the imaging optics 14 on an additional lens 18, which serves for imaging observation radiation from a central, the laser beam axis 13 intersecting region of the focusing lens 4 on the detector surface 12a of the camera 12. As can be seen in FIG. 1 b, the additional lens 18 has a significantly larger diameter than the two outer lenses 16 a, 16 b used for the stereoscopic observation. The additional lens 18 is for process observation, more precisely the observation of one in the

monitoring area 15 contained interaction area between the laser beam 2 and the workpiece 3. By the comparatively large

Diameter of the additional lens 18 is a comparatively large and thus having a high number of pixels having image on the detector surface 12a generated, whereby the resolution in the process observation is improved. It goes without saying that, unlike in FIG. 1 a, it is also possible to dispense with the additional lens 18 and thus with the process observation. In this case, the distance in the X direction between the two lenses 16a, 16b is typically shortened in comparison to the illustration in FIGS. 1a, b.

Subsequently, with reference to FIG. 2a-c, as in an evaluation device 19 of the device 1, the focus position F, F ', F "of the laser beam 2 relative to Workpiece 3 can be determined by a comparative evaluation of the two recorded images B1, B2.

In the representation of the two images B1, B2 produced by the lenses 16a, 16b, the focus position F of the laser beam 2 is located on the upper side 3a of the workpiece 3, which in the present example corresponds to a desired focus position of the workpiece machining. The two images B1, B2 respectively capture a region 15 to be monitored

Section of the surface 3a of the plate-shaped workpiece 3, which has a roughness and thus a surface structure, which is exemplified in Fig. 2a. As can be seen from Fig. 2a, the two are through the one

Images B1, B2 of the surface 3a and the structures on the surface of the workpiece 3 in the monitored, from the one reference contour forming inner contour 5b of

Laser processing nozzle 5 limited area 15 identical and in particular have no lateral offset in the X direction. The two images B1, B2 are offset on the detector surface 12a by a distance A in the X direction, which is correlated with the distance between the two lenses 16a, 16b or substantially corresponds thereto.

In the illustration of the two images B1, B2 shown in FIG. 2b, the focus position F 'of the laser beam 2 is above the top surface 3a of the workpiece 3. As can be seen in FIG. 2b, the one shown in the images B1, B2 is too monitoring area 15 of the workpiece 3 is not identical, but the surface structures to be recognized in the images B1, B2 are laterally offset from each other, namely the first image B1 to the right, ie in the positive X direction, while the imaged surface structures in the second image B2 after on the left, ie shifted in the negative X-direction, as indicated in each case by an arrow. The amount of the lateral offset between the imaged surface structures of the workpiece 3 in the two images B1, B2 depends on the distance of the focal position F 'from the workpiece 3, the lateral offset increasing as the distance between the focal position F' and the workpiece 3 increases this offset represents a measure of the deviation of the focus position F 'from the desired focus position F on the upper side 3 a of the workpiece 3. As in Fig. 2b also to is recognized, takes in the focus position shown F 'above the workpiece 3 and the distance A' between the two of the inner contour 5b of

Laser processing nozzle 5 limited images B1, B2 on the detector surface 12a from. Whether the distance A or A 'between the two images B, B2 at a

Shifting the focus position F 'in the direction of the laser processing head 1 increases or decreases depends on the imaging principle used for the generation of the images B1, B2.

In the representation of the two images B1, B2 shown in FIG. 2c, the focus position F "of the laser beam 2 is below the workpiece 3. As can be seen in FIG. 2c, the surface structures of the workpiece to be recognized in the images B1, B2 are 3 laterally offset from each other, namely in the first image B1 to the left, ie in the negative X direction, while the imaged surface structures in the second image B2 are shifted to the right, ie in the positive X direction, as indicated in each case by an arrow Amount of the lateral offset between the imaged surface structures of the workpiece 3 in the two bounded by the inner contour 5b images B1, B2 is a measure of the deviation of the focus position F "of the target focus position F at the top of the 3a

3. As can also be seen in FIG. 2c, the distance A "between the two images B1, B2 delimited by the inner contour 5b of the laser processing nozzle 5 also increases on the detector surface 12a.

As can be seen from a comparison of FIG. 2 b with FIG. 2 c, the direction of the lateral offset of the two images B 1, B 2 depends on whether the focus position is above or below the workpiece 3, so that the comparative analysis of FIG two images B, B2, in which the lateral offset, for example using a block matching algorithm or by a

Frequency analysis is determined, the focus position relative to the workpiece 3 can be determined not only in magnitude, but also in the direction. The same applies to the distance A, or Α ', A "between the two images B1, B2 on the

Detector surface 12a, which is also a measure of the focus position F and F ', F ", but here relative to the reference contour formed by the nozzle inner contour 5b, represents. Deviations of the focus position from the desired focus position F on the upper side 3 a of the workpiece 3 typically occur during workpiece machining unintentionally, since the refractive index of the focusing lens 4 is temperature-dependent, as can be seen from FIG. 3, in which the refractive index n of FIG

Focusing lens 5 for different radiation powers of the incident

Laser beam 2 is shown. In Fig. 3, the beam density (in kW / cm ² ) is shown, which impinges on the focusing lens 4 depending on the location or the radius coordinate and increases with increasing radiation power (in kW). Since the thermal load or the temperature of the focusing lens 4 can not or can not be predicted accurately enough during the machining process in order to adapt the focus position to the desired focus position F, the above-described determination of the focus position is advantageous for determining the target focus position F during the machining process in a desired, typically constant value.

For the regulation of the focus position F or F ', F "to the desired focus position, the laser processing head has a control or regulating device 20, with which the evaluation device 19 is in signal communication Regulation of the whole

Laser processing process and acts in the present case on a further arranged in the beam path of the laser beam 2 adaptive deflection mirror 21, more precisely on the optical surface 21 a, the curvature of which can be adjusted in a known per se. The curvature of the adaptive

Deflection mirror 21 influences the focus position F or F ', F "in

The curvature can be adjusted by means of the control device 20 in such a way that the thermally induced deviation of the focus position from the desired focus position F ', F "is just compensated on the adaptive

Deflection mirror 21 is acted on until the situation shown in Fig. 2a occurs, i. until the structures identified in the two images B1, B2 no longer have a lateral distance from one another.

It is understood that the target focus position F does not necessarily have to lie on the upper side 3 a of the workpiece 3, but that this also to the top surface 3 a of the Workpiece 3 can be arranged at a distance. In this case as well, the control / regulation device 20 can be used to regulate to a predetermined lateral distance between the structures to be recognized in the two images B1, B2, which corresponds to the desired target focus position. Additionally or alternatively, the control of the focus position F or F ', F "also on the basis of

Distance A or Α ', A "between the two images B1, B2 done by this distance A or Α', A" is controlled to a desired distance A, which a target focus position and a desired focal length of the focusing lens 4 corresponds to the laser processing head 1. In particular, a coarse adjustment of the focus position F or F ', F "can take place with the aid of the distance A or Α', A". Also, based on a comparison between the distance A or Α ', A "and the lateral offset between the in the two images B1, B2 to be recognized

Surface structures of the distance D between the laser machining nozzle 5 and the workpiece 3 and the top 3a of the workpiece 3 are determined.

Specifically, to determine the distance D, the difference between the

Distances of the same surface structure in the two images B1, B2 to the edge formed by the reference contour 5b of the respective image B1, B2 determined (in the X direction). This difference is determined by a known, e.g. assigned by test measurements or calculated functional relationship of the distance D to the workpiece 3 assigned. It is understood that instead of the above-described determination of the lateral offset between the surface structures to be recognized in the images B1, B2, other features of the workpiece 3 can also be used to determine the lateral offset,

For example, (heat) images of the process lighting or the like may also be used by the evaluation device 19 for the image evaluation.

The control / regulating device 20 can also be used to control the focus position of the imaging optics 14. For this purpose, the control device 20 acts on a device 32 for displacing the lenses 17a, 17b in the beam direction 13 of the laser beam 2, more precisely for varying the relative distance between the lenses 17a, 17b. For reasons of simplicity, the focus position of the imaging optics 14 is denoted by the same reference symbols F, F ¹ , F "as the focus position of the laser beam 2. By controlling the focus position F ', F', F" of FIG Imaging optics 19 can be ensured that the surface 3a of the

Workpiece 3 is arranged in the depth of focus range, so that the surface 3a of the workpiece 3 is sharply imaged on the detector surface 12a. For the regulation of the focus position F, F ', F "to the desired focus position on the workpiece 3, the distance A or Α', A" between the two images B1, B2 is controlled to a predetermined or calculated by test measurements target distance ,

As can be seen from FIGS. 4 a - c, cylindrical lenses 16 a, 16 b which are only in the X direction but not in the imaging optics 14 can be used instead of spherical lenses, which are each assigned to an observation direction R 1, R 2 have an imaging effect in the Y direction. In this case, the additional, centric lens is also formed as a cylindrical lens 18a, which also produces an optical effect only in the X direction. Another, aligned in the Y direction cylindrical lens 18b is used to generate an image in the Y direction. By the crossed cylindrical lenses 16a, b, 18a and 18b, the available imaging cross section on the detector surface 12a can be well utilized.

The imaging optics 14 shown in Fig. 5a-c also has a plurality of crossed first and second cylindrical lenses 22, 23, which in a

Raster arrangement 24 are arranged to produce a number of 5 x 5 = 25 images on the detector surface 12 a. The raster arrangement 24 of lens elements 22, 23 can be used to determine a spatially resolved determination of

To allow wavefront aberrations, which are caused by the thermally loaded focusing lens 4. On the basis of the wavefront aberrations, the beam focusing by means of the focusing lens 4 by a suitable one of

Focusing lens 4 upstream beam shaping can be optimized by means of known per se, not described here in detail beam-shaping optical elements. Alternatively or additionally, a coaxial observation of the workpiece 3 for the process monitoring can be improved by a suitable correction.

For example, the observation beam path 7 by the adaptation of

Apertures and / or distances between imaging optical elements and / or be adjusted by freely adjustable mirror. An alternative embodiment of the imaging optical system 14 with an imaging lens 25 and a beam deflection device in the form of a deflection prism 26 is shown in FIGS. 6a, b. The deflection prism 26 has four wedge-shaped sections with planar surfaces 26a-d arranged at an angle to the observation radiation or to its beam axis, which are arranged around a central, planar region 27. The first two surfaces 26a, b serve as Strahlumlenkbereiche to

Deflection of the incident observation radiation in the X direction so that it is not perpendicular to the center plane of the imaging lens 25 impinges on this and a first and second image B1, B2 on the detector surface 12a generated, which are spaced apart along the X axis.

The third surface 26c and the fourth surface 26d serve as corresponding

Beam redirecting regions for generating third and fourth images B3, B4 on the detector surface 12a, which are spaced apart along the Y direction. The central area 27, which does not deflect the observation radiation, serves the purpose of

Generation of a centric in the beam path of the observation radiation

arranged image B on the detector surface 12a, which as shown above can be used for process observation. By generating four images B1, B2 and B3, B4, which are compared in pairs with each other, more information about the focusing lens 4 can be obtained, in particular, an indication of wavefront aberrations or on

different thermal loads in the two directions (X and Y) are obtained. Also, if necessary, a comparative evaluation of three or all four images B1, B2 or B3, B4 in the evaluation device 19 can take place in order to determine the significance of the correlation and thus the precision in the determination of the correlation

Focusing position F, F ', F "increase.

In the embodiment shown in Fig. 6a, b results in a total of

Approximately convex geometry of the deflection prism. That in Fig. 7a, b

shown deflecting prism 26 differs from that shown in Fig. 6a, b only in that it has a substantially concave geometry, whereby the assignment of the images B1, B2 to the partial beams 7a, 7b of

Observation beam path 7 is reversed and corresponds to the assignment shown in Fig. 1. The assignment of the partial beams or the beam of the Observation beam 7 to the images B1, B2 and B3, B4 is in the

Identification of the direction of the change of the focus position F or F ', F "(toward and away from the workpiece 3.) Another embodiment of an imaging optics with a beam deflection device 26, which is in the form of two mirrors with beam deflection regions is formed in the form of plane mirror surfaces 26a, 26b, is shown in Fig. 8a. Since the two mirror surfaces 26a, 26b are tilted towards each other, the

incident observation radiation 7 is reflected in different directions and applies in the form of two of each observation direction R1, R2 associated observation beams 7a, 7b at different locations on the detector surface 12a, there to produce a first and second image B1, B2.

Another possibility for generating two (or more) images B1, B2 is shown in FIG. 8b. There are focused in the area of

Observation beam 7 behind a lens 17 two blocks 28a, 28b

(plane-parallel plates) arranged of quartz glass, which have two parallel end faces and serve as Strahlversatzeinrichtung. The focused

Observational radiation impinges on each of the beam entrance side of a respective block 28a, 28b at an angle and exits at the same angle offset in parallel at the opposite beam exit side again. Due to the larger refractive index in the optically denser medium of the block 28a, 28b, the observation radiation in the quartz glass material extends at a smaller angle to the normal direction perpendicular to the entrance or exit surface. The part of the observation radiation entering a respective block 28a, 28b respectively forms an observation beam 7a, 7b associated with a respective observation direction R1, R2, the two observation beams 7a, 7b laterally impinging on the detector surface 12a due to the beam offset and displaced there laterally relative to one another Create pictures B1, B2.

In the example shown in FIG. 8b, as in the example shown in FIG. 6b, the observation beams 7a, 7b intersect, since the normal directions (perpendicular to the beam entry or exit surface) of the mutually tilted blocks 28a, 28b are in the beam path behind the blocks 28a, 28b intersect. It goes without saying that the observation beams 7a, 7b can also run as shown in Fig. 7b, provided that the blocks 28a, 28b are tilted in opposite directions to each other, ie, when their normal directions intersect in front of the lens 17 in the beam path.

By comparing the two images, the focusing position F, F ', F "of the

Laser beam 2 can be determined. The same applies, of course, also to the imaging optics 14 described in conjunction with FIGS. 6a, b and 7a, b or the images B or B1 to B4 taken with them. It is understood that in the examples described above in the beam path of the

Observation radiation 7 in addition one or more (fixed) aperture can be provided to hide parts of the observation radiation 7, which should not reach the detector surface 12a or not required for the formation of the two observation beams 7a, 7b.

In a variant which is not shown in the drawing, a beam splitter can be used to form two observation beams R1, R2 associated with the respective observation direction R1, R2 using two or more observation beams 7a on the basis of at least one characteristic varying over the beam cross section , 7b dividing parts. The beam splitter can be designed, for example, for the transmission or reflection of a radiation component of the observation beam path 7 on the basis of the wavelength, the polarization or the power of the observation radiation. For example, a high-power observation beam 7b originating at the center of the observation beam path 7 can be transmitted to the beam splitter, and an observation beam 7a originating from the edge region of the observation beam path 7 and having a lower power can be reflected. Figures 9a, b show another way of forming two of each

Observation direction R1, R2 associated observation beams 7a, 7b, which differs from the possibilities described above in that the observation beams 7a, 7b formed in temporal succession. As shown in FIGS. 9 a, b, a diaphragm 31 is for this purpose in the imaging optical system 14 provided, which is rotatably mounted about a central axis of rotation B, so that moves the position of an eccentrically arranged aperture 31 a on a circular arc about the axis of rotation B during rotation. One each by the

Aperture 31 a passing part of the observation beam path 7 forms an observation beam 7 a, 7 b. Due to the arrangement of the diaphragm 31 in the focused by a lens 17 beam path of the imaging optical system 14, the observation beams 7a, 7b from different, for example, diametrically opposite areas of the observation beam path 7 temporally successively imaged on the same location on the detector surface 12a. The images taken in succession by the camera 12 can be evaluated comparatively as described above for determining the focus position F, F ', F "of the laser beam 2 by means of the evaluation device 19.

It is understood that instead of a mechanically adjustable diaphragm 31, an electrically adjustable diaphragm, for example in the form of an LCD array, can be used, in which individual pixels or groups of pixels are electronically switched on or off.

be turned off to produce the aperture effect. Also, the mechanical aperture 31, unlike in Fig. 9a, b shown transversely to

Observation beam 7, for example, in the XY plane moves or

be moved to temporally successive different parts of the

Observation beam 7 shield or open for observation. The diaphragm 31 can also be realized in the form of one or more hinged and zuklappbarer elements and it can also be arranged in succession multiple apertures to realize the temporally successive generation of the images.

10 shows a further exemplary embodiment of a device 1 in the form of a laser processing head for focusing a laser beam 2 on a workpiece 3, which essentially differs from the device 1 shown in FIG. 1 in that only a single image B1 from the camera 12 to

monitoring area 15 and the reference contour forming inner contour 5b of the laser processing nozzle 5 is received. For this purpose, from the image capture device 9 by means of a shutter 31 a (single)

Observation beam 7a formed by means of the imaging optics 14, in the example shown, two lenses 17a, 17b in a telescope arrangement for adjusting the Beam cross-section of the observation beam 7a to the detector surface 12a of the camera 12 to the image B1 on the detector surface 12a and possibly additionally a higher-resolution image from an observation direction R coaxial with

To generate high energy beam 2, as described above in connection with FIG. 1.

As can be seen in Fig. 11a, b, which the image B1, more precisely a

Section of the detector surface 12a, show at different focus positions F, F 'of the laser beam 2, changes in a change of the focus position F, F' and the position P, P 'of the reference contour forming inner contour 5b of

Laser processing nozzle 5 within the image B1 and on the detector surface 12a.

In the illustration shown in FIG. 11a, the focus position F of the laser beam 2 is located on the upper side 3a of the workpiece 3, which in the present example corresponds to the desired focus position. In the illustration shown in FIG. 11 b, the focus position F 'of the laser beam 2 is located above the upper side 3a of FIG

Workpiece 3 and the position P 'of the inner contour 5b is offset laterally (in the negative Y direction) relative to the position P shown in FIG. 11a. The amount of the lateral offset between the positions P, P 'in the captured image B1 depends on the distance of the focus position F' from the workpiece 3. The lateral offset increases with increasing distance between the focus position F 'and the

Workpiece 3 too, so that this offset is a measure of the deviation of

Focus position F 'of the target focus position F at the top 3a of the workpiece 3 represents. The lateral offset can be e.g. by means of a correlation of the

captured image B1 with a reference image that was taken at the desired target focus position F. Alternatively, the lateral offset can be determined by determining a characteristic position, for example the geometric center of gravity or a specific geometric feature, eg an object edge, in the captured image B1 and the reference image. The positional deviation between the characteristic positions in the two images can be determined by comparison and corresponds to the lateral offset. Whether with a shift of the focus position F 'in the direction of the

Laser processing head 1, the displacement of the inner contour 5b of

Laser processing nozzle 5 takes place in the captured image B1 in the positive or in the negative Y-direction, depends on the imaging principle used for the generation of the image B1. The relationship between the direction of the lateral offset of the inner contour 5b and the direction of displacement of the focus position F is unique for a given imaging principle, so that, based on the direction of the lateral offset on the direction of displacement

Focus position F can be closed.

As indicated in Fig. 10, the aperture 31 may be formed slidably and stand for the control of the displacement with the evaluation device 19 and / or with the control / regulating device 20 in signal communication. By shifting the diaphragm 31, the portion of the focusing lens 4 can be adjusted, which is traversed by the observation beam 7 a, whereby the

Observation direction R1 and the observation angle can be changed, which has been found to be advantageous for certain applications.

Also in the case of the apparatus 1 shown in FIG. 10, with the aid of the control / regulating device 20, another can be arranged in the beam path of the laser beam 2

arranged optical element which causes a beam shaping or focus adjustment, in this case, an adaptive deflection mirror 21, more precisely on the optical surface 21 a, acted to the focal position F and F 'in the beam propagation direction 13 of the laser beam 2 to a target To fix focus position. Also, an effect on other optical elements which a

Beam shaping or focus adjustment, for example, a variable focal length lens (e.g., a liquid lens) or one in the position in

Beam path sliding lens is possible. On the basis of the lateral offset of the inner contour 5b or from the amount of the required for the focus correction or the control of the focus position of the imaging optics 14 displacement of the lens 17a and the lens 17b may be on a shift of the focus position F, F ', F "of the laser beam. 2 be closed, which can be corrected in the laser beam 2 controlling. The control / regulating device 20 can also be used to control the focus position of the imaging optics 14 by acting on a displacement device 32 for displacement of the lenses 17a, 17b in the beam direction 13 of the laser beam 2, as described above in connection with FIG. In this way it can be ensured that the surface 3a of the workpiece 3 is always imaged sharply on the detector surface 12a.

In summary, in the manner described above, the focus position F or F ', F "of the laser beam 2 during workpiece machining can be determined and corrected if necessary the focus position ensures that the workpiece 3 is located in the focal plane of the focusing lens 4. In addition to the improvement of the process quality, with appropriate control of the focus position of the imaging optics 14 and the centric

taken picture B of the surface 3a of the workpiece 3, which is the

Process observation serves "sharply" through the focusing lens 4, i.e. without

Defocussing, thereby improving process observation.

Claims

1 WO 2014/191061 PCT / EP2013 / 069029 claims

1 . Device (1) for determining a focus position (F, F ', F ") of a

High-energy beam (2), in particular a laser beam, in the beam direction (13) of the high-energy beam (2) relative to a workpiece (3) and / or relative to a reference contour (5b) of the device (1), comprising:

a focusing element (4) for focusing the high-energy beam (2) onto the workpiece (3),

an image detection device (9) for detecting a region (15) to be monitored on the surface (3a) of the workpiece (3) and / or the

Reference contour (5b) by means of a through the focusing element (4) extending observation beam path (7), wherein the

Image detection device (9) is designed to form at least one observation beam (7a) which is not coaxial with the high-energy beam (2).

is associated with extending observation direction (R1) and an imaging optics (14) for generating at least one image (B1) of the monitored

Area (15) and / or the reference contour (5b) from the at least one observation direction (R1) includes, as well as

an evaluation device (19) for determining the focus position (F, F \ F ") in the beam direction (13) of the high-energy beam (2) by evaluating the at least one recorded image (B1).

2. Apparatus according to claim 1, wherein the evaluation device (19) is formed, the focus position (F, F ', F ") in the beam direction (13) of the high-energy beam (2) based on a position (P, P') of the reference contour ( 5b) in the at least one recorded image (B1).

3. Device according to claim 1, wherein the image capture device (9) for

Forming at least one further observation beam (7b) is formed, which is associated with a further observation direction (R2; R), wherein the

Imaging optics (14) for generating at least two images (B1, B2, B3, B4) of the area to be monitored (15) and / or the reference contour (5b) 2

WO 2014/191061 PCT / EP2013 / 069029 the at least two different observation directions (R1, R2) is formed, and wherein

the evaluation device (19) for determining the focus position (F, F ', F ") of the high-energy beam (2) is formed by comparative evaluation of the recorded images (B1, B2; B3, B4).

4. Device according to one of the preceding claims, which is a

Lighting source (10) for illuminating the upper side (3a) of the workpiece (3) in particular in the area to be monitored (15) and / or for illuminating the reference contour (5b).

5. Device according to one of the preceding claims, wherein the

Observation beam (7) of the image capture device (9) for detecting the area to be monitored (15) on the surface (3a) of the workpiece (3) has an image detection area (5a) which is bounded by the reference contour (5b).

6. Device according to one of claims 3 to 5, wherein the

Evaluation device (19) for determining the focus position (F, F ', F ") of the high-energy beam (2) relative to the workpiece (3) by comparing

Evaluation of the images (B1, B2, B3, B4) of the surface (3a) of the workpiece (3) in the area to be monitored (15) is formed.

7. Device according to one of claims 3 to 6, wherein the imaging optics (14) at least two of a respective observation direction (R1, R2)

associated imaging optical elements (22, 16a, 16b).

8. Apparatus according to claim 7, wherein the imaging optical elements as cylindrical lenses (22, 16 a, 16 b) are formed.

9. Apparatus according to claim 7 or 8, wherein the imaging optical

Elements (22) form a lens array (24).

10. Device according to one of claims 3 to 9, wherein the imaging optics 3

WO 2014/191061 PCT / EP2013 / 069029

(14) a deflecting device (26) with at least two of a respective one

Observation direction (R1, R2, ...) associated Strahlumlenkbereichen (26a, 26b, 26c, 26d).

11. The device according to claim 10, wherein the deflection device has at least one deflecting prism (26).

12. Device according to one of claims 3 to 11, wherein the

Image capture device (9) for forming the at least two observation beams (7a, 7b) associated with a respective observation direction (R1, R2; R1, R) has a beam offset device (28a, 28b).

13. Device according to one of claims 3 to 12, wherein the

Image capture device (9) for forming the at least two observation beams (7a, 7b) associated with a respective observation direction (R1, R2, R1, R) is formed at different times.

14. Device according to one of claims 3 to 13, wherein the

Image detection device (9) for forming the at least two observation beams (7a, 7b) associated with a respective observation direction (R1, R2, R1, R) has at least one diaphragm (31).

15. Device according to one of claims 3 to 14, wherein the imaging optics (14) for generating at least three images (B1, B2, B3, B4) of the area to be monitored (15) and / or the reference contour (5b) from

different observation directions (R1, R2, ...) is formed.

16. Device according to one of the preceding claims, wherein the

Imaging optics (14) an imaging optical element (18) for generating an image (B) of the area to be monitored (15) on the surface (3a) of the workpiece (3) from an observation direction (R) coaxial with

High energy beam (2).

17. The apparatus of claim 16, wherein the evaluation device (19) for

comparative evaluation of the coaxial to the high energy beam (2) 4

WO 2014/191061 PCT / EP2013 / 069029 recorded image (B) and at least one non-coaxial with the

High-energy beam (2) recorded image (B1 to B4) is formed.

18. Device according to one of the preceding claims, wherein the

Image detection means (9) for receiving the at least one image (B1 to B4, B) through a nozzle opening (5a) of a laser processing nozzle (5) for passage of the laser beam (2) on the workpiece (3) is formed.

19. The apparatus of claim 18, wherein a nozzle inner contour (5 b) of the

Laser processing nozzle (5) forms the reference contour.

20. Device according to one of the preceding claims, in which the

Image capture device (9) has at least one detector, in particular a camera (12), with a detector surface (12a) on which the at least one image (B1 to B4, B) is generated.

21.Vorrichtung according to one of claims 3 to 20, wherein the

Evaluation device (19) is formed by a comparative evaluation of the recorded images (B1 to B4, B) a distance (D) between the

Reference contour (5a) and the top (3a) of the workpiece (3) to determine.

22. Device according to one of the preceding claims, further comprising: means (21) for changing the focus position (F, F \ F ") of the

High energy beam (2) in the beam direction (13), as well

a control and / or regulating device (20) for controlling and / or regulating the focus position (F ', F ") of the high-energy beam (2) to a desired focus position (F).

23. Device according to one of the preceding claims, further comprising: means (32) for changing the focus position (F, F ', F') of the

Imaging optics (14) in the beam direction (13) of the high-energy beam (2), and a control and / or regulating device (20) for controlling and / or regulating the focus position (F ¹ , F ") of the imaging optics (14) to a target Focus position (F). 5

WO 2014/191061 PCT / EP2013 / 069029

24. Method for determining a focus position (F, F \ F ") of a

High-energy beam (2), in particular a laser beam, in the beam direction (13) of the high-energy beam (2) relative to a workpiece (3) and / or relative to a reference contour (5b) of a device (1) having a focusing element (4) for focusing of the high energy beam (2) on the workpiece (3), comprising:

Detecting a region (15) to be monitored on the surface (3a) of the workpiece (3) and / or the reference contour (5b) by means of an observation beam path (7) passing through the focusing element (4), generating at least one image (B1 to B4 ) of the area to be monitored (15) and / or the reference contour (5b) by forming at least one

Observation beam (7a) associated with a non-coaxial to the high energy beam (2) extending observation direction (R1), and

Determining the focus position (F, F ', F ") in the beam direction (13) of

High energy beam (2) by evaluating the at least one recorded image (B1).

25. The method of claim 24, wherein the focus position (F, F \ F ") in

Beam direction (13) of the high energy beam (2) based on a position (P, P ') of the reference contour (5b) in the at least one recorded image (B1) is determined.

26. Method according to claim 24, wherein at least one further observation beam (7b) assigned to a further observation direction (R2; R) is formed by at least two images (B1 to B4) of the area to be monitored (15) and / or the reference contour (5b) from at least two different observation directions (R1, R2) to produce, wherein the focus position (F, F ', F ") of the high energy beam (2) by comparative evaluation of

recorded images (B1, B2, B3, B4) is determined.

27. Computer program product having code means adapted to perform all steps of the method according to any one of claims 24 to 26, when the computer program runs on a data processing system.